Air conditioner

ABSTRACT

An air conditioner is provided that may include a main body having an air inlet and an air outlet; a filter received in the main body to filter air; a heat exchanger configured to allow heat exchange between a refrigerant and air suctioned into the main body; and a lamp module configured to radiate ultraviolet (UV) rays and infrared (IR) rays to the heat exchanger. The lamp module may include a porous main body, a plurality of UV lamps, and a plurality of IR lamps. The plurality of UV lamps and the plurality of IR lamps may be arranged in parallel on one surface of the porous main body at predetermined intervals.

CROSS-REFERENCE TO RELATED APPLICATION(S)

The present application claims priority under 35 U.S.C. 119 and 35 U.S.C. 365 to Korean Patent Application No. 10-2016-0093738, filed in Korea on Jul. 22, 2016, which is hereby incorporated by reference in its entirety.

BACKGROUND 1. Field

An air conditioner is disclosed herein.

2. Background

Generally, an air conditioner controls at least one of a temperature, a humidity, or a purification of an indoor air to generate a conditioned air to be suitable for a user. The air conditioner may use a refrigerating cycle of a refrigerant to control a temperature, and a humidity. The air conditioner may include a compressor, a condenser, an expander, and an evaporator as a refrigerant flow path. Indoor air may be suctioned via an inlet to the condenser or the evaporator in which the air is subject to heat exchange and then the air may be discharged via an air outlet.

The air conditioner may include a filter or dust collector to control a purification level of the air. Further, indoor air may be suctioned via an air inlet into the air conditioner and then may be purified using a purification unit or device. The purified air may be discharged via an air outlet out of the air conditioner.

Recently, a UV sterilizer device has been provided in the air conditioner to purify the air in the air conditioner. One example of this approach is disclosed in KR application publication No. 10-2006-0035144 published on Apr. 26, 2006, which is hereby incorporated by reference and in which a UV sterilizer device extends along one surface of the heat exchanger. This prior art UV sterilizer device has a large UV lamp, and thus, has a shortcoming in terms of a space efficiency and air channel. When the larger UV lamp is disposed on the surface of the heat exchanger, the air may not be sterilized uniformly along the front of the heat exchanger. Further, the related art air conditioner including only the UV lamp may not prevent the production of molds caused by moisture remaining in the air conditioner during operation or after operation stops due to an air cooling operation.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments will be described in detail with reference to the following drawings in which like reference numerals refer to like elements, and wherein:

FIG. 1 is a perspective view of an air conditioner according to an embodiment in a turned-on state;

FIG. 2 is a perspective view of the air conditioner according to an embodiment in a turned-off state;

FIG. 3 is an exploded perspective view of the air conditioner according to an embodiment;

FIG. 4 is a vertical cross-sectional view illustrating a state when a wind-direction adjustment member in FIG. 1 discharges and guides conditioned air to an indoor upper space;

FIG. 5 is a perspective view of an air conditioner according to another embodiment;

FIG. 6 is an exploded perspective view of the air conditioner of FIG. 5;

FIG. 7 is a partially cut-away perspective view of an air conditioner according to another embodiment;

FIG. 8 is a partially enlarged perspective view of a UV sterilization module in the air conditioner according to another embodiment;

FIGS. 9A-9B are perspective views illustrating positions of a UV sterilization module, a heat exchanger, and a fan in an air conditioner according to an embodiment;

FIGS. 10A-10B show an example of a UV sterilization module according to an embodiment having metal rails;

FIGS. 11A-11B are diagrams for describing power energies measured in a given region when a single related art UV lamp is employed;

FIGS. 12A-12B are diagrams for describing power energies measured in a given region when a parallel combination of multiple UV lamps according to an embodiment is employed;

FIGS. 13 to 15 illustrate an embodiment of an air conditioner including a UV lamp and an infrared (IR) lamp in a main body;

FIGS. 16 to 18 illustrate an embodiment of an air conditioner including a UV lamp and an IR lamp in a main body;

FIGS. 19 to 24 illustrate another embodiment of an air conditioner including a UV lamp and an IR lamp in a main body;

FIGS. 25 to 30 illustrate yet another embodiment of an air conditioner including a UV lamp and an IR lamp in a main body;

FIGS. 31 to 33 illustrate still another embodiment of an air conditioner including a UV lamp and an IR lamp in a main body;

FIGS. 34 to 36 illustrate still another embodiment of an air conditioner including a UV lamp and an IR lamp in a main body;

FIGS. 37 to 39 illustrate still another embodiment of an air conditioner including a UV lamp and an IR lamp in a main body; and

FIGS. 40 to 42 illustrate a porous main body rotation mechanism of a lamp module.

DETAILED DESCRIPTION

Examples of various embodiments are illustrated in the accompanying drawings and described further below. It will be understood that the description herein is not intended to limit the claims to the specific embodiments described. On the contrary, it is intended to cover alternatives, modifications, and equivalents as may be included within the spirit and scope of the present disclosure as defined by the appended claims.

Example embodiments will be described in more detail with reference to the accompanying drawings. The present disclosure, however, may be embodied in various different forms, and should not be construed as being limited to only the illustrated embodiments herein. Rather, these embodiments are provided as examples so that this disclosure will be thorough and complete, and will fully convey the aspects and features of the present disclosure to those skilled in the art.

It will be understood that when an element or layer is referred to as being “connected to”, or “coupled to” another element or layer, it can be directly on, connected to, or coupled to the other element or layer, or one or more intervening elements or layers may be present. In addition, it will also be understood that when an element or layer is referred to as being “between” two elements or layers, it can be the only element or layer between the two elements or layers, or one or more intervening elements or layers may also be present.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the present disclosure. As used herein, the singular forms “a” and “an” are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms “comprises”, “comprising”, “includes”, and “including” when used in this specification, specify the presence of the stated features, integers, s, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, s, operations, elements, components, and/or portions thereof. As used herein, the term “and/or” includes any and all combinations of one or more of the associated listed items. Expression such as “at least one of” when preceding a list of elements may modify the entire list of elements and may not modify the individual elements of the list.

Spatially relative terms, such as “beneath,” “below,” “lower,” “under,” “above,” “upper,” and the like, may be used herein for ease of explanation to describe one element or feature's relationship to another element s or feature s as illustrated in the figures. It will be understood that the spatially relative terms are intended to encompass different orientations of the device in use or in operation, in addition to the orientation depicted in the figures. For example, if the device in the figures is turned over, elements described as “below” or “beneath” or “under” other elements or features would then be oriented “above” the other elements or features. Thus, the example terms “below” and “under” can encompass both an orientation of above and below. The device may be otherwise oriented for example, rotated 90 degrees or at other orientations, and the spatially relative descriptors used herein should be interpreted accordingly.

Unless otherwise defined, all terms including technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this inventive concept belongs. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the relevant art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present disclosure. The present disclosure may be practiced without some or all of these specific details. In other instances, well-known process structures and/or processes have not been described in detail in order not to unnecessarily obscure the present disclosure.

Description will now be given in detail according to exemplary embodiments disclosed herein, with reference to the accompanying drawings. For the sake of brief description with reference to the drawings, the same or equivalent components may be provided with the same reference numbers, and description thereof will not be repeated. In general, a suffix such as “module” and “unit” may be used to refer to elements or components. Use of such a suffix herein is merely intended to facilitate description of the specification, and the suffix itself is not intended to give any special meaning or function. In the present disclosure, that which is well-known to one of ordinary skill in the relevant art has generally been omitted for the sake of brevity. The accompanying drawings are used to help easily understand various technical features and it should be understood that the embodiments presented herein are not limited by the accompanying drawings. As such, the present disclosure should be construed to extend to any alterations, equivalents and substitutes in addition to those which are particularly set out in the accompanying drawings.

It will be understood that, although the terms “first”, “second”, “third”, and so on may be used herein to describe various elements, components, regions, layers and/or sections, these elements, components, regions, layers and/or sections should not be limited by these terms. These terms are used to distinguish one element, component, region, layer or section from another element, component, region, layer or section. Thus, a first element, component, region, layer or section described below could be termed a second element, component, region, layer or section, without departing from the spirit and scope of the present disclosure.

Hereinafter, embodiments will be described with reference to attached drawings.

FIG. 1 is a perspective view of an air conditioner according to an embodiment in a turned-on state. FIG. 2 is a perspective view of an air conditioner of FIG. 1 in a turned-off state. FIG. 3 is an exploded perspective view of the air conditioner of FIG. 1. FIG. 4 is a vertical cross-sectional view illustrating a state when a wind-direction adjustment member or adjuster in FIG. 1 discharges and guides a conditioned air to an indoor upper space.

In this embodiment, the air conditioner may include a main body 2 having an air inlet 4 to receive indoor air and an air outlet 6 to discharge conditioned air. In this embodiment, the air conditioner may be configured to receive air from the air inlet 4 and to condition the air therein and then to discharge the conditioned air via the air outlet 6. The air conditioner may be implemented as a stand-type air conditioner, a ceiling-mounted air conditioner, or a wall-mounted air conditioner, for example. Hereinafter, a reference may be made to a wall-mounted air conditioner by way of example.

The main body 2 may be installed or provided indoors and may be a singular component or a combination of multiple components. In the latter case, the main body 2 may include a chassis 10, a front frame 20, a suction grill 21, a front panel 28, and a discharge unit or device 30. Hereinafter, the chassis 10 may be referred to as a rear frame 10.

In the main body 2, the air inlet 4 may be formed in or at front and top portions thereof and the air outlet 6 may be formed in or at a bottom portion thereof. The front panel 28 may move in a front-rear direction or may pivot downward or upward to form an air suction channel between the front surface and the front panel 28.

Alternatively, in the main body 2, the air inlet 4 may be formed in or at a top portion thereof and the air outlet 6 may be formed in or at a bottom portion thereof. The main body 2 may have an opening for maintenance of the conditioner at the front portion thereof, and the front panel 28 may be arranged to open and close the front surface and the opening of the main body 2.

Hereinafter, a reference will be made to an example in which the air inlet 4 is formed at a top portion of the main body 2, and the air outlet 6 is formed at a bottom portion of the main body 2. The front panel 28 may be formed as a front appearance of the air conditioner and may be configured to pivot around an upper edge thereof or to move in a front-rear direction.

The chassis 10 may be mounted to a wall and may define an air flow channel therein. The chassis 10 may be function as a housing or rear frame to receive various components.

The chassis 10 may have a wind channel guide 12 formed therein to guide an air from the air inlet 4 to the air outlet 6. At one of first and second or left and right sides of the wind channel guide 12, an electronics board 13 may be disposed or provided on which various electronic components may be mounted.

The wind channel guide 12 may define an air channel for a fan 54, which is discussed hereinafter. The wind channel guide 12 may include first and second or left and right guides 15, 16 expanding in a front direction from the chassis 10, and a middle guide 17 between the left and right guides 15, 16. At one of the left and right guide 15, 16, a heat exchanger supporter 18 may be disposed or provided to support a heat exchanger 60 and to define an air channel. From the electronics board 13, a motor installation 14 may protrude in a frontward direction to receive a fan motor 52. On the electronics board 13, a control box 70 may be disposed or provided to control the air conditioner. The control box 70 may be disposed or provided together with a controller (not shown) for the fan motor 52 of an air blower 50, and a wind-direction adjustment member driver 35, for example.

The front frame 20 may be provided at a front of the chassis 10 to define a space with the chassis 10. The front frame 20 may define a wind channel with the wind channel guide 12 of the chassis 10, and may cover the electronics board 13 on the chassis 10 to protect the electronics board 13. The front frame 20 may have openings in top and front portions thereof. The opening in the top portion may act as the air inlet 4. A front opening 5 may act as an access passage for a filter 80 or UV sterilization module or sterilizer 760.

The front frame 20 may have the front opening 5 in a front of the wind channel guide 12 of the chassis 10. An upper opening may be formed at an upper portion in a front of the wind channel guide 12 of the chassis 10.

The suction grill 21 may allow indoor air to be suctioned into the main body 2 and may protect a bottom of the body. The suction grill 21 may be formed in a grill shape on the top opening of the front frame 20.

The discharge unit 30 may discharge conditioned air out of the main body 2. The discharge unit 30 may be assembled to at least one of the chassis 10 or the front frame 20 via a fastener or a hook.

On or at a top of the discharge unit 30, a drain 32 may be provided to collect condensed water falling from the heat exchanger 60. The drain 32 may be coupled to a drain connection hose 33 to guide the condensed water out of the main body 2. The air outlet 6 may be formed on the bottom of the drain 32.

The discharge unit 30 may have a wind-direction adjuster to control a wind-direction of air passing through the air outlet 6. The wind-direction adjuster may guide the air passing through the air outlet 6 and control the wind-direction. The wind-direction adjuster may include a wind-direction adjustment member or adjuster 34 rotatably disposed or provided at the main body 2, more particularly, at the discharge unit 30, and the wind-direction adjustment member driver 35 to rotate the wind-direction adjustment member 34.

The wind-direction adjustment member 34 may include a horizontal wind-direction adjustment member or adjuster to control a horizontal wind-direction of the air passing through the air outlet 6, and a vertical wind-direction adjustment member or adjuster to control a vertical wind-direction of the air passing through the air outlet 6. The wind-direction adjustment member driver 35 may be coupled to the horizontal wind-direction adjustment member to allow the horizontal wind-direction adjustment member to rotate around a vertical axis. Further, the wind-direction adjustment member driver 35 may be coupled to the vertical wind-direction adjustment member to allow the vertical wind-direction adjustment member to rotate around a horizontal axis.

The wind-direction adjustment member 34 may rotate to allow one of the horizontal wind-direction adjustment member or vertical wind-direction adjustment member to open and close the air outlet 6. Hereinafter, a reference will be made to a configuration where the vertical wind-direction adjustment member closes and opens the air outlet 6, the wind-direction adjustment member driver 35 is provided at one of first and second or left and right sides of the discharge unit 30 to drive the rotation of the vertical wind-direction adjustment member as a wind-direction adjustment motor.

The main body 2 may receive the air blower 50 to suction the air into the air inlet 4 and move the air into the main body 2 and discharge the air to the air outlet 6. Further, the main body 2 may receive the heat exchanger 60 to allow heat exchange between the air and refrigerant. Further, the main body 2 may receive the filter 80 to purify the air suctioned into the air inlet 4 and a filter frame 90 for the filter 80.

The air blower 50 may include the fan motor 52 seated in the motor installation 14 formed in the chassis 10, more particularly, the electronics board 13, and the fan 54 disposed or provided at a rotation axis of the fan motor 52 and located on the wind channel guide 12. The fan 54 may be implemented as a horizontally-elongated cross flow fan between the wind channel guides 15,16,17, more particularly, between the left and right channel guides 15,16. The air blower 50 may further include a motor cover 56 disposed or provided at the chassis 10 to cover the fan motor 52.

The heat exchanger 60 may be located between the air inlet 4 and the fan 54. For this, the heat exchanger 60 may be located at a rear of the front frame 20 and may have a lower end disposed or provided on or at a top of the drain 32. The heat exchanger 60 may include a vertical portion 62 on or at the top of the drain 32, a front tilted portion 64 from a top of the vertical portion 62 to a top of a rear portion, and a rear tilted portion 66 from a top of the front tilted portion 64 to a bottom of a rear portion.

The filter frame 90 may be provided between the air inlet 4 and the heat exchanger 60. The filter frame 90 may have openings 91 formed therein to receive the filter 80.

In this embodiment, the air conditioner may include a controller (not shown) provided in the main body 2 to control the fan motor 52, and the wind-direction adjustment member driver 35, for example. The controller may control the fan motor 52 and wind-direction adjustment member driver 35 during an air cooling operation. A cool conditioned air may be guided to the wind-direction adjustment member 34 and then be discharged therefrom. The wind-direction adjustment member 34 may spread the conditioned air via a rotation thereof. In an opening mode of the wind-direction adjustment member driver 35, the wind-direction adjustment member 34 may open the air outlet 6 via a rotation of the wind-direction adjustment member driver 35. The rotation of the fan motor 52 may rotate the fan 54. The rotation of the fan 54 may allow the indoor air to be suctioned via the air inlet 4 into the main body 2 and then to be purified via the filter 80 and then to heat exchange with the heat exchanger 60. Then, the air may pass through the air outlet 6 via the wind-direction adjustment member 34 and then be discharged therefrom.

In a swing discharge mode, the controller may allow forward/reverse rotations of the wind-direction adjustment member driver 35 during the rotation of the fan motor 52. Further, the wind-direction adjustment member 34 may translate vertically via the wind-direction adjustment member driver 35 to allow a vertical spreading of the air passing through the air outlet 6.

FIG. 5 is a perspective view of an air conditioner according to another embodiment. FIG. 6 is an exploded perspective view of the air conditioner of FIG. 5.

In this embodiment, the air conditioner is implemented as a stand-type air conditioner. The stand-type air conditioner may include a base rear panel 210 that contacts a floor and having an inner space therein, and a main body rear panel 250 coupled to a top of the base rear panel 210 and having an air inlet 251 a formed therein. Further, the stand-type air conditioner may include one or more connector 230 coupled to the base rear panel 210 at an inside thereof, and a base front panel 220 coupled to the connector 230. Further, the stand-type air conditioner may include a main body front panel 290 coupled to the base front panel 220 at a bottom thereof and coupled to the main body rear panel 250 at a side portion thereof and having an air outlet 290 a.

The base rear panel 210 may be supported on a floor on which the air conditioner is installed or provided. The base rear panel 210 may have an inner space defined therein. For this, the base rear panel 210 may have a polyhedral shape with an open front portion. The base rear panel 210 may have a curved rear surface. The base rear panel 210 may have a bottom that contacts the floor.

The base rear panel 210 may have an inner side wall coupled to the connector 230. In the inner space in the base rear panel 210, a circuit element to control the air conditioner, and an electronics box (not shown) to receive various electronic components may be provided. The base rear panel 210 may have a front portion coupled to the base front panel 220. The base rear panel 210 may have a top portion coupled to the main body rear panel 250.

The connector 230 may be coupled to the base rear panel 210 at an inner side thereof. The connector 230 may have a vertical elongate column shape. A plurality of the connector 230 may be provided. The plurality of the connector 230 may include a first or left connector 230-1 coupled to an inner first or left surface of the base rear panel 210, and a second or right connector 230-2 coupled to an inner second or right surface of the base rear panel 210. The left connector 230-1 and right connector 230-2 may be horizontally symmetrical.

The connector 230 may reinforce a strength of the base rear panel 210, and may support a shroud panel 260 having one or more air blowing module 240 and a guide panel 270 coupled thereto. The connector 230 may be coupled to the base rear panel 210 at a bottom and a partial side surface of the connector 230. The connector 230 may be coupled to the shroud panel 260 at a top of the connector 230. The connector 230 may be coupled to the base front panel 220 at a front of the connector 230.

The main body rear panel 250 may be coupled to a top of the base rear panel 210 to form an upper rear appearance of the air conditioner. The main body rear panel 250 may be formed of a hollow polyhedral shape with open front and rear surfaces.

The main body rear panel 250 may have the air inlet 251 a to suction indoor air therein. The inlet 251 a may be formed in a rear portion of the main body rear panel 250. The air blowing module 240 may be turned on to generate an air flow. Thus, the air may be suctioned into the inlet 251 a and then the air may pass through an indoor heat exchanger 110 to the shroud panel 260.

The main body rear panel 250 may include a main body rear panel body 251 having the inlet 251 a formed at a rear portion thereof, and a rear panel filter 252 mounted to the main body rear panel body 251 at a rear portion thereof to cover the inlet 251 a. The rear panel filter 252 may filter the suctioned air into the inlet 251 a. The rear panel filter 252 may be coupled to the main body rear panel body 251 at a rear thereof. The main body rear panel 250 may be coupled to the shroud panel 260 at a front of the panel 250. The main body rear panel 250 may be coupled to the base rear panel 210 at a bottom of the panel 250.

In the main body rear panel 250, the indoor heat exchanger 110 may be disposed or provided. The indoor heat exchanger 110 may be provided between the main body rear panel 250 and the shroud panel 260 to allow heat exchange between the air flowing into the inlet 251 a of the main body rear panel 250 and a refrigerant. The air may be cooled or heated via the heat exchange with the refrigerant in the indoor heat exchanger 110 and then may be passed to the shroud panel 260. The indoor heat exchanger 110 may be implemented as a combination of a tube and fins. In the tube, the refrigerant may flow. The fins may realize the heat exchange.

The air blowing module 240 may suction air into the inlet 251 a of the main body rear panel 250 and discharge the air via the air outlet 290 a in the main body front panel 290. When the air blowing module 240 turns on, the air suctioned into the inlet 251 a may pass through the indoor heat exchanger 110 and move through a shroud hole 260 a in the shroud panel 260 to the air blowing module 240. Then, the air blowing module 240 may blow the air to move through a guide hole 270 a of a guide panel 270 to the outlet 290 a of the main body front panel 290.

A plurality of the air blowing module 240 may be provided. In this embodiment, a number of the air blowing module 240 is 2; however, embodiments are not limited thereto. In this embodiment, the two air blowing modules 240 are arranged vertically. The two air blowing modules 240 may correspond to two shroud holes 260 a in the shroud panel 260, respectively. The two air blowing modules 240 may be coupled to the guide panel 270 at a rear of the panel 270.

The air blowing module 240 may include an air blower motor 242, an air blower motor bracket 243 to couple the air blower motor 242 to the guide panel 270 at a rear of the panel 270, and an air blowing fan 241 to rotate together with a rotation of the air blower motor 242 to create a flow of air. The air blowing fan 241 may be implemented as a centrifugal fan to receive air axially and then discharge the air radially. The air blowing fan 241 may be configured such that an air suction direction may be oriented toward the shroud hole 260 a of the shroud panel 260. After the air is radially discharged from the air blowing fan 241, the air may flow toward a front of the shroud panel 260 and then pass through the guide hole 270 a of the guide panel 270. When a plurality of air blowing modules 240 is provided, a plurality of the air blowing fan 241 may be provided. Further, the plurality of the air blowing fans 241 may correspond to the plurality of shroud holes 260 a, respectively.

The shroud panel 260 may be configured to guide the air from the inlet 251 a in main body rear panel 250 to the air blowing module 240. The shroud panel 260 may define the shroud hole 260 a therein, through which the air from the indoor heat exchanger 110 may move to the air blowing module 240. A plurality of the shroud hole 260 a may be provided. The plurality of the shroud holes 260 a may correspond to the plurality of air blowing modules 240, respectively. In this embodiment, two shroud holes 260 a may be vertically arranged to correspond to the two air blowing modules 240 respectively.

A surrounding portion of the shroud hole 260 a of the shroud panel 260 may be formed in a dome shape to receive the air blowing module 240 therein. Thus, using the air blowing module 240, the flowing air may be guided to the front thereof.

The shroud panel 260 may be coupled to the connector 230 at a bottom of the panel 260. The shroud panel 260 may be coupled, at a rear thereof, to the main body rear panel 250. The shroud panel 260 may be coupled, at a front thereof, to the guide panel 270.

The guide panel 270 may be configured to guide flowing air using the air blowing module 240 to the outlet 290 a. The guide panel 270 may have the guide hole 270 a defined therein to guide the air from the air blowing module 240 to the outlet 290 a. A plurality of the guide hole 270 a may be provided. In this embodiment, two guide holes 270 a may be formed at lateral sides relative to a central line C, respectively. Each guide hole 270 a may be vertically elongated. Each guide hole 270 a may taper from a middle point to bottom and top points, respectively. Each guide hole 270 a may be bent toward the central line C at upper and lower portions thereof. The guide hole 270 a may be opened or closed by a door 280. Thus, when a plurality of the guide hole 270 a is provided, a plurality of doors 280 may be provided.

The guide panel 270 may have the air blowing module 240 mounted thereto at a rear of the panel 270. In this embodiment, two air blowing modules 240 are vertically coupled to the rear portion of the guide panel 270. In a front of the guide panel 270, the door 280 may be provided. In this embodiment, in a front of the guide panel 270, two doors 280 are horizontally arranged.

The guide panel 270 may be at least partially curved such that the door 280 rotates and slides on and along the guide panel 270. In this embodiment, two doors 280 are horizontally arranged, and thus, the guide panel 270 may have a curved front portion at each of lateral sides relative to the vertical central line C. In other words, the curved front portion may be convex toward a front direction to form an arc shape.

The guide panel 270 may be coupled to the shroud panel 260 with the air blowing module 240 being interposed therebetween, thereby to form a single unit. In this embodiment, the guide panel 270, the air blowing module 240, and the shroud panel 260 may be collectively referred to as an air blowing unit or blower 190. That is, the air blowing unit 190 may include the guide panel 270, the air blowing module 240, and the shroud panel 260.

The door 280 may open or close the guide hole 270 a and the outlet 290 a. The door 280 may be rotatably coupled to the air blowing unit 190. The door 280 may be rotatably coupled to the guide panel 270 or the shroud panel 260 of the air blowing unit 190. In this embodiment, the door 280 is rotatably coupled to the guide panel 270. The door 280 may partially slide on a front surface of the guide panel 270 to open and close the guide hole 270 a. Further, the door 280 may partially slide on a rear surface of the main body front panel 290 to open and close the outlet 290 a. That is, the door 280 may partially slide between the guide panel 270 and the main body front panel 290 to open and close the guide hole 270 a and the outlet 290 a concurrently.

The base front panel 220 may form a lower front appearance of the air conditioner. The base front panel 220 may cover the open front of the base rear panel 210 coupled to the connector 230. The base front panel 220 may be implemented as a curved plate. The base front panel 220 may be coupled to the connector 230 at the rear of the base front panel 220, and the base front panel 220 may be coupled to the main body front panel 290 at a top of the base front panel 220.

The main body front panel 290 may form an upper front appearance of the air conditioner. The main body front panel 290 may have the air outlet 290 a to discharge the air passing through guide hole 270 a using the air blowing module 240. The outlet 290 a may correspond to the guide hole 270 a in terms of a shape. In this embodiment, the outlets 290 a may be two as the two guide holes 270 a are defined. The two outlets 290 a may be define at both lateral sides relative to the central line C. Each air outlet 290 a may be vertically elongated. Each outlet 290 a may be bent toward the central line C at upper and lower portions thereof. Each outlet 290 a may taper from a middle point to top and bottom points thereof, respectively. The outlet 290 a may be opened and closed by the door 280.

The main body front panel 290 may be implemented as a curved plate. The main body front panel 290 may be coupled, at a bottom thereof, to the base front panel 220, and may be coupled, at a side portion thereof, to the main body rear panel 250. The main body front panel 290 may have an input/output hole 290 b to partially expose an input/output module 300. The input/output hole 290 b may have a circular form.

The input/output module 300 may be configured to receive a user command or display an operation state of the air conditioner. The input/output module 300 may be coupled to the main body front panel 290 at a rear of the panel 290 to be partially exposed through the input/output hole 290 b to the outside.

The air conditioner may be applied to the wall-mounted air conditioner, and/or stand-type air conditioner. Hereinafter, for the sake of the convenience, a reference will be made to the wall-mounted air conditioner.

FIG. 7 is a partially cut-away perspective view of an air conditioner according to another embodiment. As shown in FIG. 7, the air conditioner in accordance with this embodiment may include a UV sterilization module 760 provided in a main body 700. The UV sterilization module 760 may include a porous main body 762 and a UV lamp 764.

In this embodiment, the main body 700 may include a front panel 710, and a chassis 720. The main body 700 may receive a wind-direction adjustment member or adjuster 730, a fan 740, a heat exchanger 750, the porous main body 762, and the UV lamp 764. As shown in FIG. 7, the air conditioner may include all of the components as described with reference to FIGS. 1 to 4 in addition to the front panel 710, the chassis 720, the wind-direction adjustment member 730, the fan 740, and the heat exchanger 750. With reference to FIG. 7, only the front panel 710, the chassis 720, the wind-direction adjustment member 730, the fan 740, the heat exchanger 750, and the UV sterilization module 760 will be shown and described.

The main body 700 may have an air inlet 712 defined in a top thereof and an air outlet 714 defined in a bottom of thereof. The front panel 710 may define a front portion of the air conditioner. The main body 700 may have the air inlet 712 defined in a top of the air conditioner and the air outlet 714 defined in a bottom of the air conditioner.

The front panel 710 may form a front appearance of the air conditioner, and may be configured to pivot around a top portion thereof to maintain inner components of the air conditioner. Further, in this embodiment, the front panel 710, the chassis 720, the wind-direction adjustment member 730, the fan 740, and the heat exchanger 750 may have the same configurations and functions as described with reference to FIGS. 1 to 4.

In this embodiment, the UV sterilization module 760 may be disposed or provided upstream of the heat exchanger 750 in terms of an air flow path. The UV sterilization module 760 may be disposed or provided in the air suction channel between the front panel 710 and the heat exchanger 750.

The porous main body 762 may be configured to allow passage of air therethrough. The porous main body 762 may have holes 766 formed therein. For example, the porous main body 762 may be implemented as a porous plate having the holes 766 formed therein. Alternatively, the porous main body 762 may be implemented as a mesh of wires wherein the holes 766 may be defined between the wires. Hereinafter, the porous main body 762 may be referred to as a mesh, a web, a main body, a body, a support body, a porous lamp support body, a web main body, a mesh body, or a web body, for example.

The porous main body 762 may have the holes 766 to guide the air to the UV lamp 764. Each hole 766 may have a size larger than or equal to a predetermined size to minimize a channel resistance due to the porous main body 762. Further, the porous main body 762 may be made of an elastic material. The porous main body 762 may have a round surface that conforms to a shape of the heat exchanger 750 or may have at least one curve. The porous main body 762 may be disposed or provided between the main body 700 and the heat exchanger 750.

The UV sterilization module 760 may emit heat using the UV lamp 764. The porous main body 762 may be made of a heat-resistance material. Further, the porous main body 762 may be made of a metal material rather than a plastic material. The porous main body 762 may be made of a material endurable against heat and humidity. For example, the porous main body 762 may be made of aluminum. The aluminum Al may include a pure aluminum and an aluminum alloy.

The porous main body 762 may be disposed or provided upstream of the UV lamp 764 and the heat exchanger 750 in terms of an air flow path. The porous main body 762 may have a photocatalyst coating formed thereon. Thus, the air may be deodorized using the porous main body 762 and then may move to the UV lamp 764 and the heat exchanger 750. That is, when the porous main body 762 has a photocatalyst coating formed thereon, an odorized substance in the air may be minimally or hardly attached to the UV lamp 764. When the odorized substance is attached on the UV lamp 764, the UV lamp 764 may be deteriorated.

For example, the photocatalyst coating may include a TiO₂, ZnO, CdS, ZrO₂, V₂O₃, or WO₂ coating. The air that flows into the air inlet 712 may be deodorized using the porous main body 762, and then, may be sterilized using the UV lamp 764. Thus, the deodorized and sterilized air may be passed to the heat exchanger 750.

The porous main body 762 may be configured to allow a minimum air flow interference in the air flow channel. Further, while the air passes through the porous main body 762, the air may flow adjacently to the UV lamp 764. Thus, the air may receive a strong UV intensity. This may lead to improvement in sterilization by the UV sterilization module 760.

The UV sterilization module 760 may include a plurality of the UV lamp 764. Thus, the plurality of UV lamps 764 may be spaced from each other. The plurality of UV lamps 764 may be at least partially arranged in a series manner. The plurality of UV lamps 764 may be entirely arranged in a series manner. The plurality of UV lamps 764 may have a predetermined spacing between them. The plurality of UV lamps 764 may be at least partially arranged in a parallel manner. The plurality of UV lamps 764 may be entirely arranged in a parallel manner.

The plurality of UV lamps 764 may be spaced from the porous main body 762. The plurality of UV lamps 764 may be at least partially disposed or provided between the porous main body 762 and the heat exchanger 750. Further, some of the plurality of UV lamps 764 may be disposed or provided between the porous main body 762 and the heat exchanger 750, while the other of the plurality of UV lamps 764 may be disposed or provided between the porous main body 762 and front panel 710. The UV lamps 764 between the porous main body 762 and front panel 710 may sterilize the air passing between the air inlet 712 and porous main body 762. Subsequently, the UV lamps 764 between the porous main body 762 and the heat exchanger 750 may sterilize the air passing through the porous main body 762.

As described above, the UV lamps may be distributed across the porous main body 762, and the porous main body 762 may have the photocatalyst coating. Thus, the air may be sterilized, a first time, between the air inlet 712 and porous main body 762. Subsequently, the air may be deodorized using the porous main body 762, and then, the air may be sterilized, a second time, between the porous main body 762 and the heat exchanger 750.

The UV sterilization module 760 may include one or more holder (not shown) to support the UV lamp 764. The holder may support the UV lamp 764 such that the UV lamp 764 is spaced from the porous main body 762. A plurality of holders may support the UV lamps 764 respectively. A pair of the holders may support a single UV lamp 764. The UV sterilization module 760 may include a plurality of pairs of the holders. The plurality of pairs of the holders may be spaced from each other.

In one embodiment, the UV sterilization module 760 may include a plurality of UV lamps 764, a power supply (not shown), and an electrical line (not shown). The UV lamp 764 may be implemented as an external electrode type. Therefore, the UV lamp 764 may have a first electrode at one or a first side thereof, and a second electrode at the other or second side thereof. The first electrode and the second electrode may be formed by coating a conductive solder liquid from an outside of the UV lamp 764. Further, the first electrode and second electrode may be formed by coating a silver paste. Furthermore, the first electrode and second electrode may be formed by applying a carbon-nano tube and curing it. That is, the UV lamp 764 and the first electrode and the second electrode may be individually formed. Thus, an electric field may be generated between the first electrode and the second electrode. Then, the electric field may electrically discharge an emission material in the UV lamp 764 to generate UV rays. As the material enclosed in the UV lamp 764 does not contact the first electrode and the second electrode, the UV lamp 764 may have a less amount of heat, to increase a life span of the UV lamp 764.

The power supply may supply power to the UV lamp 764. The power supply may stabilize a current to be supplied to the UV lamp 764. Further, the power supply may generate a high voltage required to generate UV rays in the UV lamp 764. That is, the power supply may be configured to change an output frequency and drive voltage based on a drive frequency and drive voltage for driving the plurality of UV lamps 764. For example, the power supply may act as an inverter, and a stabilizer, for example.

The electric line may connect the power supply and the plurality of UV lamps 764. To be specific, the electric line may connect the first electrode and the second electrode and the power supply. Further, the electric line may realize a parallel connection between the plurality of UV lamps 764 and the power supply. That is, the parallel connection between the power supply and the plurality of UV lamps 764 may allow the plurality of UV lamps 764 to turn on concurrently. Further, when the plurality of UV lamps 764 includes a defective UV lamp, the defective UV lamp may be simply replaced.

Although the UV lamp 764 has been described as an external electrode fluorescent lamp, embodiments are not limited thereto. The electrodes may be disposed or provided within the UV lamp.

Hereinafter, a configuration of the UV lamp 764 will be described. The UV lamp 764 as an external electrode fluorescent lamp may be formed in a hollow bar or tube shape. Further, the UV lamp 764 may have a sealed inner space. The UV lamp 764 may be made of quartz or borosilicate or a glass containing quartz or borosilicate. Further, the UV lamp 764 may have an emission material enclosed therein to generate the UV rays. The emission material may be discharged via an electric field generated between the first electrode and the second electrode at both ends of the UV lamp 764 respectively to generate the UV rays.

For example, the emission material may include at least one of Hg, Ne, Xe, Kr, Ar, XeBr, XeCl, KrBr, KrCl, or CH₄. Further, except for Hg, all of the emission materials may be present in a gas state. Further, the emission material may be enclosed in the UV lamp 764 under a constant pressure. For example, the emission material may be enclosed in the UV lamp 764 under an upper or middle pressure. The UV lamp 764 may have a small diameter to facilitate an installation of the lamp in the air conditioner. For example, the UV lamp 764 may have a diameter of about 1 mm to about 7 mm.

When the UV lamp 764 has a diameter below about 1 mm, the lamp may be damaged and filling of the emission material may be not easy. When the UV lamp 764 has a diameter above about 7 mm, air flow resistance due to the lamp may increase. Further, a voltage to discharge the emission material in the UV lamp 764 may increase, thereby increasing power consumption.

The UV lamp 764 may be oriented horizontally in the air conditioner. The UV lamp 764 may be oriented horizontally length-wise. Further, the UV lamp 764 may have a thickness to withstand an inner pressure of the gas enclosed in the UV lamp 764. For example, the UV lamp 764 may have a thickness of about 0.2 mm to about 2 mm. The diameter, length, and thickness of the UV lamp 764 may be not limited to the above dimensions.

The UV lamp 764 may have the first electrode and the second electrode externally disposed or provided at both sides of the UV lamp 764, respectively. Further, the first electrode and the second electrode may be made of a conductive solder liquid at both sides of the UV lamp 764, respectively. Further, the first electrode and the second electrode may be formed by applying a silver paste. Further, the first electrode and the second electrode may be formed by applying and curing a carbon nano-tube (CNT). For example, the UV lamp 764 may be immersed, at both ends thereof, into the conductive solder liquid, and the conductive solder liquid may be cured to form the first electrode and the second electrode.

That is, an outer surface of the UV lamp 764 may dip into the conductive solder liquid, thereby to simplify a manufacturing process thereof. Further, conductive material and conductive solder liquid may include one or more of Ag, carbon nano-tube (CNT), Cu, and Pt. Thus, each of the first electrode and the second electrode may extend from both ends of the UV lamp 764 in a lengthwise direction of the UV lamp 764. Further, each of the first electrode and the second electrode may have a length of at least about 1 cm to about 3 cm from both ends of the UV lamp 764.

When each of the first electrode and the second electrode has a length below about 1 cm, it may be difficult to discharge the emission material in the UV lamp 764. That is, the first electrode and the second electrode may have a small area lowering a discharge efficiency of the emission material. When each of the first electrode and the second electrode has a length above about 3 cm, it may not be difficult to discharge the emission material in the UV lamp 764, but the UV emission area may be smaller due to a smaller area of the first electrode and the second electrode.

The UV sterilization module 760 may sterilize a harmful substance in the air using a parallel connection of the plurality of UV lamps 764 disposed or provided on the porous main body 762, which the air having flowed into the air inlet 712 passes through the porous main body 762 toward the heat exchanger 750. The UV lamp 764 may generate UV rays having a wavelength of about 250 nm to about 260 nm with a strong sterilization against a microorganism. The wavelength of about 250 nm to about 260 nm may have a sterilization effect 1000 to 10000 times larger than a sterilization effect of a near UV.

When the UV rays are irradiated into a DNA of a microorganism, a molecular structure of thymine among bases of the DNA may be intensively destroyed. Thymine absorbing the UV rays may be attached to adjacent thymine or cytosine. Thus, the thymine may be polymerized to stop the replication of DNA. Further, UV rays oxidize phospholipids and proteins forming a cell membrane to suppress life activity of bacteria.

The UV sterilization module 760 may be installed or provided in various locations in the air conditioner. For example, the UV sterilization module 760 may be located between the front panel 710 and the front frame (not shown) of the air conditioner. That is, the porous main body 762 may be coupled to the front panel 710 at a rear of the panel 710 to direct the UV lamp 764 toward the heat exchanger 750.

Further, the UV sterilization module 760 may be located between the front frame and the filter (not shown) of the air conditioner. That is, the porous main body 762 may be coupled to the front frame at a rear of the frame to direct the UV lamp 764 toward the heat exchanger 750.

Further, the UV sterilization module 760 may be located between the filter frame (not shown) and the heat exchanger 750 of the air conditioner. That is, the porous main body 762 may be coupled to the filter frame at a rear thereof to direct the UV lamp 764 toward the heat exchanger 750.

FIG. 8 is a partially enlarged perspective view of a UV sterilization module in the air conditioner according to another embodiment. As shown in FIG. 8, the UV sterilization module 760 may include porous main body 762, UV lamp 764, holes 766, and holder(s) 768.

In one embodiment, the UV sterilization module 760 may have holes 766 formed in a polygonal, circular, and/or an elliptical shape. Further, a variation of size of the holes 766 may lead to adjustment of a flow rate of an air passing through the porous main body 762.

The porous main body 762 may have one or more holder 768 at a front thereof. A plurality of the holder 768 may be arranged to be spaced from each other. Further, the porous main body 762 may have a plurality of holders 768 on each of both sides thereof. Each of the plurality of holders 768 may be made of a metal, and may be structured to surround the UV lamp 764.

Further, the porous main body 762 may have holders 768 on one side thereof where the holders 768 may be spaced from each other. The UV lamp 764 may be fitted into the holders 768 at both ends of the UV lamp respectively. Further, the porous main body 762 may have holders 768 arranged at a left, middle, and right points respectively on one side thereof. The UV lamp 764 may be fitted into the holders 768 at the left, middle, and right portions of the UV lamp, respectively.

The porous main body 762 may have a waterproof sealing or seal (not shown) around the holder 768 to prevent corrosion, for example, of the electrodes and holder 768 of the UV lamp 764. Further, although not shown in FIG. 8, the UV sterilization module 760 may include a metal rail (not shown) provided on the porous main body 762. The metal rail may be electrically connected to the holder 768, and thus, current may flow through the metal rail and the holder 768 to the UV lamp 764. The metal rail may be connected to the plurality of holders 768, and thus, the current applied to the metal rail may flow to the plurality of holders 768. The metal rail may act as a parallel connector to realize a parallel connection of the plurality of UV lamps 764. The metal rail may be referred to as a bus bar.

The plurality of holders 768 may be arranged to be spaced from each other on one surface of the metal rail. That is, the plurality of holders 768 may be arranged on the metal rail at a predetermined distance. A water-proof sealing or seal may be provided to cover not only the electrode, and holder 768 of the UV lamp 764 but also the metal rail.

FIGS. 9A-9B are perspective views illustrating positions of a UV sterilization module, a heat exchanger, and a fan in an air conditioner according to an embodiment. As shown in FIGS. 9A-9B, in one embodiment, the air conditioner may include the UV sterilization module 760 including the porous main body 762, the UV lamp 764, the heat exchanger 750, and the fan 740. The UV sterilization module 760 may include the porous main body 762 with holes 766 having a size larger than or equal to a predetermined size so as not to interfere with the air flow.

The UV sterilization module 760 may have the porous main body 762 made of an elastic material. The porous main body 762 may be curved in a conformal manner to a shape of the heat exchanger 750. The UV sterilization module 760 may include a plurality of UV lamps 764. The plurality of UV lamps 764 may be arranged to be spaced from each other on the porous main body 762 in a parallel fashion. The porous main body 762 may include a holder (not shown) to support the UV lamp 764. The UV lamps 764 may be fitted into the holders respectively arranged on the porous main body 762 to be spaced from each other. The UV sterilization module 760 may sterilize a harmful substance in the air using a parallel connection of the plurality of UV lamps 764 disposed or provided on the porous main body 762 while the air having flowed into the air inlet 712 passes through the porous main body 762 toward the heat exchanger 750.

As described above, the porous main body 762 may be made of an elastic material to cover an entire area of the heat exchanger 750. The porous main body 762 may conform to the heat exchanger 750 in shape, and thus, may be coupled to the heat exchanger 750. The porous main body 762 may have a bent portion to realize a conformal registering of the porous main body 762 on the heat exchanger 750. Further, the porous main body 762 may include a first porous main body 912 corresponding to a first or vertical portion of the heat exchanger 750, a second porous main body 914 corresponding to a second or front tilted portion of the heat exchanger 750, and a third porous main body 916 corresponding to a third or rear tilted portion of the heat exchanger 750. Further, although not shown in FIG. 9, in one embodiment, the porous main body of the UV sterilization module 760 may vary in a size and shape depending on a size and shape of the UV lamp.

FIGS. 10A-10B show an example of a UV sterilization module according to an embodiment having metal rails. As shown in FIGS. 10A-10B, in one embodiment, the UV sterilization module 760 may include porous main body 762, a plurality of UV lamps 764, a plurality of holes 766, a plurality of holders 768, and metal rails 769.

The porous main body 762 may have the plurality of holes 766 to receive air. The air into the plurality of holes 766 may be sterilized using the plurality of UV lamps 764. The metal rails 769 may be provided at first and second or left and right sides of the porous main body 762, respectively, with a given length. The plurality of holders 768 may be arranged to be spaced from each other on the metal rails 769. Thus, the plurality of holders 768 may be disposed or provided on first and second or left and right portions of the porous main body 762. Each of the plurality of UV lamps 764 may be fitted or provided with a pair of holders at the left and right portions of the porous main body, respectively.

In one embodiment, the UV sterilization module 760 may receive power from a power supply. Each UV lamp 764 may receive power via the electric line. Further, the holder 768 may be made of a metal, and the holder 768 may be connected to the electric line to supply power to each UV lamp. Further, employing the plurality of UV lamps 764 as the external electrode UV lamp may allow an easy power supply. That is, when the plurality of metal holders 768 and metal rails 769 are disposed and both metal rails 769 receive the power, all UV lamps 764 may receive the power concurrently. In this way, using the metal rails, UV lamp mounting and power supply may be facilitated.

FIGS. 11A-11B are diagrams for describing power energies measured in a given region when a single conventional UV lamp is employed. FIGS. 12A-12B are diagram for describing power energies measured in a given region when a parallel combination of multiple UV lamps according to an embodiment is employed.

In FIGS. 11A-11B, a single related art UV lamp 1000 may be used to conduct UV sterilization, while in FIGS. 12A-12B, in one embodiment, a parallel connection of ten UV lamps 1100 may be used to conduct UV sterilization.

As shown in FIGS. 11A-11B, when the single related art UV lamp 1000 or is employed works, power energy measured in an A region amounts to about 5 m W/cm²; power energy measured in a B region amounts to about 2.2 mW/cm²; power energy measured in a C region amounts to about 0.6 mW/cm²; and power energy measured in a D region amounts to about 0.9 mW/cm². As shown in FIGS. 12A-12B, in the one embodiment, when the ten UV lamps 1100 work, or are employed power energy measured in an A region amounts to about 5.1 W/cm²; power energy measured in a B region amounts to about 4.5 mW/cm²; power energy measured in a C region amounts to about 3.6 mW/cm²; and power energy measured in a D region amounts to about 3.7 mW/cm².

That is, in the one embodiment, a plurality of the UV lamps 1100 with small diameters respectively works concurrently, a high power density may be achieved due to a small spacing between the lamps, and thus, an overlapping effect may occur. In contrast, a lower power density may be achieved due to a larger spacing between the lamps, and thus, a reduced overlapping effect may occur.

Thus, an approach where the single related art UV lamp 1000 works may have a larger power consumption than the present approach where the present ten UV lamps 1100 work concurrently. Therefore, taking into account power consumption, a space efficiency, and UV sterilization, using the plurality of the UV lamps 1100 in the one embodiment may be more effective than using the single related art UV lamp.

FIGS. 13 to 42 are schematic diagrams for describing examples in which an air conditioner in accordance with embodiments uses a UV lamp and an IR lamp to sterilize air inside of a main body of the air conditioner and remove moisture.

Further, both the UV lamp and the IR lamp described with reference to FIGS. 13 to 42 may be a UV lamp and an IR lamp as an external electrode lamp which includes an electrode at the outside as described above with reference to FIG. 7. Further, the UV lamp and the IR lamp may be a uniaxial lamp in which a bar or a tube is elongated in a horizontal direction as described above with reference to FIG. 7. The UV lamp and the IR lamp described below with reference to FIGS. 13 to 42 may have a diameter of about 3 mm or about 5 mm or less.

The IR lamp described below with reference to FIGS. 13 to 42 may radiate far-infrared rays. The far-infrared rays have various useful properties, such as antibacterial effect, deodorizing effect, sterilizing effect, dehumidifying effect, and air purifying effect, for example. The far-infrared rays have a long wavelength of about 5 to about 25 μm. Due to the long wavelength, the far-infrared rays deeply penetrate an object, and thus, molecules of the object easily vibrate and heat is generated spontaneously, thus causing a rise in temperature of the inside of an air conditioner main body or a heat exchanger 60. Therefore, when the IR lamp radiates the far-infrared rays to the heat exchanger 60 while a cold refrigerant passes through the heat exchanger 60, a temperature rise of the heat exchanger 60 or a temperature drop of the heat exchanger 60 may be delayed and the sterilizing effect of the heat exchanger 60 by the far-infrared rays may be slight.

FIGS. 13 to 15 illustrate an embodiment of an air conditioner including a UV lamp and an IR lamp in a main body. As shown in FIGS. 13 to 15, in the air conditioner according to this embodiment, a heat exchanger 60 and a filter frame 90 may be disposed or provided in a main body 1300, and a lamp module 1205 including a plurality of UV lamps 1230 and a plurality of IR lamps 1240 may be disposed or provided between the heat exchanger 60 and the filter frame 90.

The filter frame 90 may be spaced from the heat exchanger 60 in an air flow direction. Between them, there may be defined a gap in which the lamp module 1205 may be disposed or provided spaced from the heat exchanger 60. This gap may be larger than an air flow direction thickness of the lamp module 1205. While the lamp module 1205 is spaced from the heat exchanger 60, the lamp module 1205 may generate UV rays and IR rays.

A porous main body 1210 of the lamp module 1205 may be disposed or provided between the heat exchanger 60 and the filter frame 90. The porous main body 1210 may face the heat exchanger 60.

The lamp module 1205 may further include a holder 1220 disposed or provided in the porous main body 1210 to support the UV lamp 1230 and the IR lamp 1240. The holder 1220 may be mounted to the porous main body 1210 such that the holder 1220 protrudes toward from a surface of the porous main body 1210 facing the heat exchanger 60.

Each UV lamp 1230 and each IR lamp 1240 may be mounted to the holder 1220 of the porous main body 1210. Each UV lamp 1230 and each IR lamp 1240 may be spaced from the porous main body 1210 via the holder 1220. Each UV lamp 1230 and each IR lamp 1240 may be spaced from the porous main body 1210 in an air flow direction, and the UV lamp 1230 may generate UV rays in the air flow direction between the porous main body 1210 and the heat exchanger 60. Further, the IR lamp 1240 may generate IR rays in the air flow direction between the porous main body 1210 and heat exchanger 60.

The porous main body 1210 may not have the holder 1220 on a surface opposite to the surface facing the heat exchanger 60. The porous main body 1210 may be coupled to the filter frame 90. The filter frame 90 may have a coupler (not shown) to which the porous main body 1210 may be detachably coupled.

The porous main body 1210 may be coupled to the filter frame 90 at the surface opposite to the surface of the body 1210 facing the heat exchanger 60. The plurality of UV lamps 1230 and the plurality of IR lamps 1240 on the surface of the porous main body 1210 facing the heat exchanger 60 may emit the UV rays and the IR rays toward the heat exchanger 60.

The air suctioned into the air inlet 4 may pass through the filter 80, the filter frame 90, and the porous main body 1210 sequentially, and may move to the heat exchanger 60. The UV lamp 1230 may emit the UV rays to sterilize the air. As the air sterilization method has been described in detail with reference to FIG. 7, redundant descriptions thereof has been omitted.

Further, the heat exchanger 60 included in the main body 1300 of the air conditioner in accordance with this embodiment may include a vertical portion at a top of the drain, a front tilted portion from a top of the vertical portion to a top of a rear portion, and a rear tilted portion from a top of the front tilted portion to a bottom of a rear portion. Therefore, in the main body 1300 of the air conditioner according to this embodiment, the plurality of IR lamps 1240 may be arranged in parallel on the surface of the porous main body 1210 facing the vertical portion of the heat exchanger 60, and the plurality of UV lamps 1230 may be arranged in parallel on the surface of the porous main body 1210 facing the front tilted portion of the heat exchanger 60.

The porous main body 1210 may have a length equal to or larger than a length of the heat exchanger 60. In contrast, the UV lamp 1230 and the IR lamp 1240 may have a length smaller than or equal to the length of the heat exchanger 60.

A spacing between the porous main body 1210 and the heat exchanger 60 may be set to an optimal distance based on experimental data. Further, the lamp module 1205 may include the plurality of UV lamps 1230 and the plurality of IR lamps 1240. The plurality of UV lamps 1230 and the plurality of IR lamps 1240 may be individually or collectively controlled based on a user input.

As illustrated in FIGS. 13 to 15, as the plurality of IR lamps 1240 may be arranged on the surface facing the vertical portion of the heat exchanger 60, it is possible to remove moisture collected in or on the vertical portion of the heat exchanger 60 after the operation stop of the air conditioner due to gravity.

FIGS. 16 to 18 illustrate another embodiment of an air conditioner including a UV lamp and an IR lamp in a main body. As shown in FIGS. 16 to 18, in the air conditioner according to this embodiment, heat exchanger 60 and filter frame 90 may be disposed or provided in a main body 1600, and a lamp module 1205 including a plurality of UV lamps 1230 and a plurality of IR lamps 1240 may be disposed or provided between the heat exchanger 60 and the filter frame 90.

The filter frame 90 may be spaced from the heat exchanger 60 in an air flow direction. Between them, there may be defined a gap in which the lamp module 1205 may be disposed or provided spaced from the heat exchanger 60. This gap may be larger than an air flow direction thickness of the lamp module 1205. While the lamp module 1205 is spaced from the heat exchanger 60, the lamp module 1205 may generate UV rays and IR rays.

A porous main body 1210 of the lamp module 1205 may be disposed or provided between the heat exchanger 60 and the filter frame 90. The porous main body 1210 may face the heat exchanger 60.

The lamp module 1205 may further include a holder 1220 disposed or provided in the porous main body 1210 to support the UV lamp 1230 and the IR lamp 1240. The holder 1220 may be mounted to the porous main body 1210 such that the holder 1220 protrudes toward from a surface of the porous main body 762 facing the heat exchanger 60.

Each UV lamp 1230 and each IR lamp 1240 may be mounted to the holder 1220 of the porous main body 1210. Each UV lamp 1230 and each IR lamp 1240 may be spaced from the porous main body 1210 via the holder 1220. Each UV lamp 1230 and each IR lamp 1240 may be spaced from the porous main body 1210 in an air flow direction, and the UV lamp 1230 may generate UV rays in the air flow direction between the porous main body 1210 and the heat exchanger 60. Further, the IR lamp 1240 may generate IR rays in the air flow direction between the porous main body 1210 and heat exchanger 60.

The porous main body 1210 may not have the holder 1220 on a surface opposite to the surface facing the heat exchanger 60. The porous main body 1210 may be coupled to the filter frame 90. The filter frame 90 may have a coupler (not shown) to which the porous main body 1210 may be detachably coupled.

The porous main body 1210 may be coupled to the filter frame 90 at the surface opposite to the surface of the body 1210 facing the heat exchanger 60. The plurality of UV lamps 1230 and the plurality of IR lamps 1240 on the surface of the porous main body 1210 facing the heat exchanger 60 may emit the UV rays and the IR rays toward the heat exchanger 60.

The air suctioned into the air inlet 4 may pass through the filter 80, the filter frame 90, and the porous main body 1210 sequentially and may move to the heat exchanger 60. The UV lamp 1230 may emit the UV rays to sterilize the air. As the air sterilization method has been described in detail with reference to FIG. 7, redundant descriptions thereof has been omitted.

Further, as shown in FIGS. 16 to 18, in the main body 1600 of the air conditioner according to this embodiment, the plurality of UV lamps 1230 may be arranged in parallel on the surface of the porous main body 1210 facing the heat exchanger 60, and the plurality of IR lamps 1240 may be arranged between the plurality of UV lamps 1230. A spacing between the plurality of UV lamps 1230 may be different from a spacing between the plurality of IR lamps 1240. Further, a spacing between the UV lamps 1230 and the IR lamps 1240 may be different.

The porous main body 1210 may have a length equal to or larger than a length of the heat exchanger 60. In contrast, the UV lamp 1230 and the IR lamp 1240 may have a length smaller than or equal to the length of the heat exchanger 60.

A spacing between the porous main body 1210 and heat exchanger 60 may be set to an optimal distance based on experimental data. Further, the lamp module 1205 may include the plurality of UV lamps 1230 and the plurality of IR lamps 1240. The plurality of UV lamps 1230 and the plurality of IR lamps 1240 may be individually or collectively controlled based on a user input.

FIGS. 19 to 24 illustrate yet another embodiment of an air conditioner including a UV lamp and an IR lamp in a main body. As shown in FIGS. 19 to 21, in this embodiment, the air conditioner may include UV lamps 1230 and IR lamps 1240 between front frame 20 and filter 80 of a main body 1900.

In this embodiment, the UV lamp 1230 and the IR lamp 1240 may have holder 1210 protruding from a surface of the porous main body 1210 facing the filter 80. The holder 1220 may support the UV lamp 1230 and the IR lamp 1240. Each UV lamp 1230 and each IR lamp 1240 may be spaced from the porous main body 1210 via the holder 1220.

In this embodiment, the holder 1220 may not be present on a front of the porous main body 1210. The porous main body 1210 may have porous main body couplers (not shown) on a surface thereof opposite to the surface facing the filter 80 to be coupled to at least one of the front frame 20 or chassis 10.

The porous main body 1210 may be curved or have at least one bent portion in the main body 1900. The porous main body 1210 may have a first region facing the front frame 20. The porous main body 1210 may have a second region facing the chassis 10. The porous main body coupler may be formed on one of the first region or and the second region, and may be formed on each of the first and second regions.

The porous main body 1210 may include a front body 1210 a facing an inner surface of the front frame 20 and an upper body 1210 b extending from the front body and facing the air inlet 4. The porous main body 1210 may further include a rear body 1210 c that extends downward from the upper body 1210 b and faces the chassis 10. The rear body 1210 c may be at least partially disposed or provided between the heat exchanger 60 and the chassis 10.

The porous main body 1210 may be coupled to the filter frame 20 and the chassis 10 at the surface opposite to the surface of the body 1210 facing the filter 80. The plurality of UV lamps 1230 arranged in parallel in a region between the porous main body 1210 and the filter 80 may emit the UV rays toward the filter 80. Similarly, the plurality of IR lamps 1240 may be arranged in parallel between the porous main body 1240 and the filter 80 to generate the IR rays toward the filter 80.

The air suctioned into the air inlet 4 may pass through the porous main body 1210, between the plurality of UV lamps 1230, and then, may pass through the filter 80 and filter frame 90 in this order and then move to the heat exchanger 60. The UV rays from the UV lamp 1230 may sterilize the air passing between the UV lamps 1230, the air passing through the filter 80, and the air passing through the heat exchanger 60. As the method of sterilizing the air by using the UV lamp has been described in detail with reference to FIG. 7, redundant descriptions thereof has been omitted.

Further, the heat exchanger 60 included in the main body 1900 of the air conditioner in accordance with this embodiment may include a vertical portion at a top of the drain, a front tilted portion from a top of the vertical portion to a top of a rear portion, and a rear tilted portion from a top of the front tilted portion to a bottom of a rear portion. Therefore, in the main body 1900 of the air conditioner according to this embodiment, the plurality of IR lamps 1240 may be arranged in parallel on the surface of the porous main body 1210 facing the vertical portion of the heat exchanger 60, and the plurality of UV lamps 1230 may be arranged in parallel on the surface of the porous main body 1210 facing the front tilted portion and the rear tilted portion of the heat exchanger 60. Further, in the main body 1900 of the air conditioner according to this embodiment, the plurality of IR lamps 1240 may be arranged in parallel on the front body portion 1210 a of the porous main body 1210, and the plurality of UV lamps 1230 may be arranged in parallel on the upper body 1210 b and the rear body 1210 c of the porous main body 1210.

Further, the IR lamps 1240 according to this embodiment may not radiate the IR rays to the heat exchanger 60 while the cold refrigerant passes through the heat exchanger 60. When the IR lamps 1240 radiate the IR rays to the heat exchanger 60 while the cold refrigerant passes through the heat exchanger 60, the temperature rise of the heat exchanger 60 or the temperature drop of the heat exchanger 60 may be delayed and the sterilizing effect of the heat exchanger 60 by the IR rays may be slight. When the air conditioner is in an operation stop state and the inside of the air conditioner is a humid condition, the IR lamps 1240 may radiate the far-infrared rays to the heat exchanger 60.

The main body 1900 of the air conditioner according to this embodiment may further include a cleanliness sensor (not shown) configured to sense air cleanliness, a humidity sensor (not shown) configured to sense humidity in the main body 1900, and a control unit or controller (not illustrated) configured to control the plurality of UV lamps 1230 and the plurality of IR lamps 1240. The cleanliness sensor may be disposed or provided between the air inlet 4 and the heat exchanger 60 in a channel.

The cleanliness sensor may include a dust sensor configured to sense an amount of dust or a gas sensor configured to detect a harmful gas in the air, for example. The cleanliness sensor may be installed or provided at a position of the air conditioner exposed to an indoor space, or may be installed or provided inside of the air conditioner. When the cleanliness sensor is installed or provided inside of the air conditioner, the cleanliness sensor may be disposed or provided between the air inlet 4 and heat exchanger 60.

The humidity sensor may be configured to measure a humidity of a space in which the heat exchanger 60 is disposed. The humidity sensor may be mounted on the heat exchanger 60. When the humidity sensor is not mounted on the heat exchanger 60, the humidity sensor may be mounted close to the heat exchanger 60 in the main body 1900.

The control unit may selectively turn on the plurality of UV lamps 1230 and the plurality of IR lamps 1240. When the UV lamps 1230 are turned on, the IR lamps 1240 may be turned off. When the IR lamps 1240 are turned on, the UV lamps 1240 may be turned off. The control unit may turn on and off the UV lamps 1230 during the operation of the air conditioner, and may turn on and off the IR lamps 1240 during the operation stop of the air conditioner.

A time and condition of turning on the UV lamps 1230 and the IR lamps 1240 may be different. The air conditioner may optimally sterilize and purify the air and sterilize and dry the heat exchanger 60 by the selective turn-on of the UV lamps 1230 and the IR lamps 1240.

The control unit may turn on the plurality of UV lamps 1230 when a fan is rotating and the air cleanliness sensed by the cleanliness sensor is out of a set or predetermined cleanliness range. The control unit may turn off the plurality of UV lamps 1230 when the fan is stopped or the air cleanliness sensed by the cleanliness sensor is within a set cleanliness or predetermined range during the turn-on of the UV lamps 1230.

The control unit may turn on the plurality of IR lamps 1240 when a operation stop time is greater than or equal to a preset or predetermined time and the humidity sensed by the humidity sensor is greater than or equal to a preset or predetermined humidity. The control unit may turn off the plurality of IR lamps 1240 when the humidity sensed by the humidity sensor is less than the preset or predetermined humidity during the turn-on of the IR lamps 1240. The control unit may turn off the plurality of IR lamps 1240 when the set or predetermined time is completed after the IR lamps 1240 are turned on.

The porous main body 1210 may have a length equal to or larger than a length of the heat exchanger 60. In contrast, the UV lamp 1230 and the IR lamp 1240 may have a length smaller than or equal to the length of the heat exchanger 60.

Further, as shown in FIGS. 22 to 24, in main body 2200 of the air conditioner according to an embodiment, the porous main body may be mounted to correspond to a shape of the heat exchanger 60 or may be mounted close to the filter 80.

FIGS. 25 to 30 illustrate yet another embodiment of an air conditioner including a UV lamp and an IR lamp in a main body. As shown in FIGS. 25 to 27, in this embodiment, the air conditioner may include UV lamps 1230 and IR lamps 1240 between front frame 20 and filter 80 of the main body 2500.

In this embodiment, the UV lamp 1230 and the IR lamp 1240 may have the holder 1210 protruding from a surface of the porous main body 1210 facing the filter 80. The holder 1220 may support the UV lamp 1230 and the IR lamp 1240. Each UV lamp 1230 and each IR lamp 1240 may be spaced from the porous main body 1210 via the holder 1220.

In this embodiment, the holder 1220 may not be present on a front of the porous main body 1210. The porous main body 1210 may have porous main body couplers (not shown) on a surface thereof opposite to the surface facing the filter 80 to be coupled to at least one of the front frame 20 or the chassis 10.

The porous main body 1210 may be curved or have at least one bent portion in the main body 2500. The porous main body 1210 may have a first region facing the front frame 20. The porous main body 1210 may have a second region facing the chassis 10. The porous main body coupler may be formed on one of the first region or the second region, and may be formed on each of the first and second regions.

The porous main body 1210 may include a front body 1210 a facing an inner surface of the front frame 20 and an upper body 1210 b that extends from the front body and faces the air inlet 4.

The porous main body 1210 may further include a rear body 1210 c that extends downwards from the upper body 1210 b and faces the chassis 10. The rear body 1210 c may be at least partially disposed or provided between the heat exchanger 60 and the chassis 10.

The porous main body 1210 may be coupled to the filter frame 20 and the chassis 10 at the surface opposite to the surface of the body 1210 facing the filter 80. The plurality of UV lamps 1230 arranged in parallel in a region between the porous main body 1210 and the filter 80 may emit the UV rays toward the filter 80. Similarly, the plurality of IR lamps 1240 may be arranged in parallel between the porous main body 1240 and the filter 80 to generate the UV rays toward the filter 80.

The air suctioned into the air inlet 4 may pass through the porous main body 1210, between the plurality of UV lamps 1230, and then, pass through the filter 80 and the filter frame 90 in this order and then move to the heat exchanger 60. The UV rays from the UV lamp 1230 may sterilize the air passing between the UV lamps 1230, the air passing through the filter 80, and the air passing through the heat exchanger 60. As the method of sterilizing the air using the UV lamp has been described in detail with reference to FIG. 7, redundant descriptions thereof has been omitted.

Further, as shown in FIGS. 25 to 27, in main body 2500 of the air conditioner according to this embodiment, the plurality of UV lamps 1230 may be arranged in parallel on the surface of the porous main body 1210 facing the filter 80, and the plurality of IR lamps 1240 may be arranged between the plurality of UV lamps 1230. A spacing between the plurality of UV lamps 1230 may be different from a spacing between the plurality of IR lamps 1240. Further, a spacing between the UV lamps 1230 and the IR lamps 1240 may be different.

Further, the IR lamps 1240 according to this embodiment may not radiate the IR rays to the heat exchanger 60 while the cold refrigerant passes through the heat exchanger 60. When the IR lamps 1240 radiate the IR rays to the heat exchanger 60 while the cold refrigerant passes through the heat exchanger 60, the temperature rise of the heat exchanger 60 or the temperature drop of the heat exchanger 60 may be delayed and the sterilizing effect of the heat exchanger 60 by the IR rays may be slight. When the air conditioner is in an operation stop state and the inside of the air conditioner is in a humid condition, the IR lamps 1240 may radiate the far-infrared rays to the heat exchanger 60.

The main body 2500 of the air conditioner according to this embodiment may further include a cleanliness sensor (not shown) configured to sense air cleanliness, a humidity sensor (not shown) configured to sense humidity in the main body 2500, and a control unit or controller (not illustrated) configured to control the plurality of UV lamps 1230 and the plurality of IR lamps 1240. The cleanliness sensor may be disposed or provided between the air inlet 4 and heat exchanger 60 in a channel.

The cleanliness sensor may include a dust sensor configured to sense an amount of dust or a gas sensor configured to detect a harmful gas in the air, for example. The cleanliness sensor may be installed or provided at a position of the air conditioner exposed to an indoor space and may be installed or provided inside of the air conditioner. When the cleanliness sensor is installed or provided inside of the air conditioner, the cleanliness sensor may be or provided disposed between the air inlet 4 and the heat exchanger 60.

The humidity sensor may be configured to measure a humidity of a space where the heat exchanger 60 is disposed or provided. The humidity sensor may be mounted on the heat exchanger 60. When the humidity sensor is not mounted or provided on the heat exchanger 60, the humidity sensor may be mounted close to the heat exchanger 60 in the main body 2500.

The control unit may selectively turn on the plurality of UV lamps 1230 and the plurality of IR lamps 1240. When the UV lamps 1230 are turned on, the IR lamps 1240 may be turned off. When the IR lamps 1240 are turned on, the UV lamps 1240 may be turned off.

The control unit may turn on and off the UV lamps 1230 during operation of the air conditioner, and may turn on and off the IR lamps 1240 during an operation stop of the air conditioner.

A time and condition of turning on the UV lamps 1230 and the IR lamps 1240 may be different. The air conditioner may optimally sterilize and purify the air and sterilize and dry the heat exchanger 60 by the selective turn-on of the UV lamps 1230 and the IR lamps 1240.

The control unit may turn on the plurality of UV lamps 1230 when a fan is being driven and the air cleanliness sensed by the cleanliness sensor is out of a set or predetermined cleanliness range. The control unit may turn off the plurality of UV lamps 1230 when the fan is stopped or the air cleanliness sensed by the cleanliness sensor is within a set or predetermined cleanliness range during the turn-on of the UV lamps 1230.

The control unit may turn on the plurality of IR lamps 1240 when the operation stop time is greater than or equal to a preset or predetermined time and the humidity sensed by the humidity sensor is greater than or equal to a preset or predetermined humidity. The control unit may turn off the plurality of IR lamps 1240 when the humidity sensed by the humidity sensor is less than the preset or predetermined humidity during the turn-on of the IR lamps 1240. The control unit may turn off the plurality of IR lamps 1240 when the set or predetermined time is completed after the IR lamps 1240 are turned on.

The porous main body 1210 may have a length equal to or larger than a length of the heat exchanger 60. In contrast, the UV lamp 1230 and the IR lamp 1240 may have a length smaller than or equal to the length of the heat exchanger 60.

Further, as shown in FIGS. 28 to 30, in the main body 2800 of the air conditioner according to this embodiment, the porous main body may be mounted to correspond to a shape of the heat exchanger 60 or may be mounted close to the filter 80.

FIGS. 31 to 33 illustrate still another embodiment of an air conditioner including a UV lamp and an IR lamp in a main body. As shown in FIGS. 31 to 33, in the air conditioner according to this embodiment, front panel 28 may be disposed or provided in a front of a main body 3100, and UV lamps 1230 and IR lamps 1240 may be disposed or provided between the front panel 28 and filter 80 to generate UV rays and IR rays.

The UV lamps 1230 and the IR lamps 1240 may have holder 1220 on a surface of a porous main body 1210 facing the filter 80. Each UV lamp 1230 and each IR lamp 1240 may be mounted on the holder 1220 and spaced from the porous main body 1210, the front panel 28, the filter 80, and heat exchanger 60.

The porous main body 1210 may have a front facing the front panel 28. The holders may not be present on the front of the porous main body 1210. The porous main body 1210 may have couplers (not shown) on a front surface to be coupled to the front panel 28.

The front surface of the porous main body 1210 may be coupled to the front panel 28 via the couplers. Thus, the plurality of UV lamps 1230 and the plurality of IR lamps 1240 arranged in parallel at a rear of the porous main body 1210 may emit the UV rays and the IR rays toward the filter 80.

The air suctioned into the air inlet 4 may pass through the filter 80 and filter frame 90 in this order and to the heat exchanger 60. The UV lamp 1230 may emit the UV rays toward the filter 80 and the heat exchanger at the front of the filter 80 and the heat exchanger 60. The air suctioned via the air inlet 4 may be sterilized by the UV rays while passing through the filter 80 and the heat exchanger 60. As the air sterilization method has been described in detail with reference to FIG. 7, redundant descriptions thereof has been omitted.

Further, the heat exchanger 60 included in the main body 3100 of the air conditioner in accordance with this embodiment may include a vertical portion at a top of the drain, a front tilted portion that extends from a top of the vertical portion to a top of a rear portion, and a rear tilted portion that extends from a top of the front tilted portion to a bottom of a rear portion. Therefore, in the main body 3100 of the air conditioner according to this embodiment, the plurality of IR lamps 1240 may be arranged in parallel on the surface of the porous main body 1210 facing the vertical portion of the heat exchanger 60, and the plurality of UV lamps 1230 may be arranged in parallel on the surface of the porous main body 1210 at which the IR lamps 1240 are not arranged.

FIGS. 34 to 36 illustrate still another embodiment of an air conditioner including a UV lamp and an IR lamp in a main body. As shown in FIGS. 34 to 36, in the air conditioner according to this embodiment, front panel 28 may be disposed or provided in front of a main body 3400, and UV lamps 1230 and IR lamps 1240 may be disposed or provided between the front panel 28 and filter 80 to generate UV rays and IR rays.

The UV lamps 1230 and the IR lamps 1240 may have holder 1220 on a surface of a porous main body 1210 facing the filter 80. Each UV lamp 1230 and each IR lamp 1240 may be mounted on the holder 1220 and spaced from the porous main body 1210, the front panel 28, the filter 80, and heat exchanger 60.

The porous main body 1210 may have a front facing the front panel 28. The holders may not be present on the front of the porous main body 1210. The porous main body 1210 may have couplers (not shown) on a front surface to be coupled to the front panel 28.

The front surface of the porous main body 1210 may be coupled to the front panel 28 via the couplers. Thus, the plurality of UV lamps 1230 and the plurality of IR lamps 1240 arranged in parallel at a rear of the porous main body 1210 may emit the UV rays and the IR rays toward the filter 80.

The air suctioned into the air inlet 4 may pass through the filter 80 and the filter frame 90 in this order and to the heat exchanger 60. The UV lamp 1230 may emit the UV rays toward the filter 80 and the heat exchanger 60 at the front of the filter 80 and the heat exchanger 60. The air suctioned via the air inlet 4 may be sterilized by the UV rays while passing through the filter 80 and the heat exchanger 60. As the air sterilization method has been described in detail with reference to FIG. 7, redundant descriptions thereof has been omitted.

Further, in the main body 3400 of the air conditioner in accordance with this embodiment, the UV lamps 1230 and the IR lamps 1240 may be alternately arranged on one surface of the porous main body 1210. After the UV lamps 1230 are arranged in parallel, the IR lamps 1240 may be arranged between the UV lamps 1230.

FIGS. 37 to 39 illustrate still another embodiment of an air conditioner including UV lamps and IR lamps in a main body. As shown in FIGS. 37 to 39, in a main body 3700 of an air conditioner according to this embodiment, UV sterilization module 1205 may be arranged to cover a front surface of filter 80 or correspond to a shape of heat exchanger 60, and an IR sterilization module 3705 may be arranged between the heat exchanger 60 and fan 54.

The UV sterilization module 1205 may include a first porous main body 1210, holder 1220, and IR lamp 1230, and the IR sterilization module 3705 may include second porous main body 3710, holder 3720, and IR lamp 3730. The second porous main body 3710 of the IR sterilization module 3705 may be rounded to correspond to a shape of the fan 54. Further, in order for the rounding processing, the second porous main body 3710 may be made of a flexible material. Moreover, in order to arrange the IR sterilization module 3705 between the heat exchanger 60 and the fan 54, a small-sized IR lamp having a small outer diameter may be used.

As the method of driving the UV sterilization module 1205 and the IR sterilization module 3705 is the same as described above in the previous embodiments, redundant descriptions thereof has been omitted.

FIGS. 40 to 42 are diagrams for describing a porous main body rotation mechanism of the lamp module. The air conditioner according to embodiments may further include a porous main body rotation mechanism 4000 to rotate the porous main body 1210. The porous main body rotation mechanism 4000 may have a rotation axis 4010 coupled to the porous main body 1210. The porous main body rotation mechanism 4000 may be implemented as a motor 4020 having the rotation axis 4010 or a motor 4020 coupled to the rotation axis 4010.

The rotation axis 4010 may be oriented in a horizontal direction. The porous main body 1210 may rotate around the rotation axis 4010. During rotation of the porous main body 1210, the plurality of UV lamps 1230 and the plurality of IR lamps 1240 may move toward or away from the heat exchanger 60. For example, among the plurality of IR lamps 1240, IR lamps 1240 disposed or provided in or at an upper portion of the porous main body 1210 may move toward the heat exchanger 60 while IR lamps 1240 disposed or provided in or at a lower portion of the porous main body 1210 may move away from the heat exchanger 60.

The rotation axis 4010 may be oriented in a vertical direction. The porous main body 1210 may rotate around the rotation axis 2510. During the rotation of the porous main body 1219, the plurality of UV lamps 1230 and the plurality of IR lamps 1240 may move toward or away from the heat exchanger 60. For example, among the plurality of UV lamps 1230 and the plurality of IR lamps 1240, left UV lamps 1230 and left IR lamps 1240 may move toward the heat exchanger 60 while right UV lamps 1230 and right IR lamps 1240 may move away from the heat exchanger 60.

In the air conditioners according to embodiments disclosed herein, configurations and methods of the embodiments described above are not limitedly applied, but all or part of the embodiments may be selectively combined so as to achieve various modifications.

Embodiments disclosed herein provide a support that supports a plurality of ultraviolet (UV) lamps and a plurality of infrared (IR) lamps and allow air to smoothly flow. Embodiments disclosed herein further provide an IR lamp arranging method for uniformly sterilizing an entire surface of a heat exchanger. Embodiments disclosed herein also provide an IR lamp for use in a wall-mounted air conditioner having a narrow space.

Embodiments disclosed herein prevent air introduced via an air inlet from concentrating on a portion of an air conditioner. Embodiments disclosed herein provide a part which supports an IR lamp employing an external electrode type to a porous main body and facilitates electrical connection.

Embodiments disclosed herein also prevent generation of molds caused by moisture in an air conditioner. Embodiments disclosed herein further remove moisture flowing in a drain direction after an operation stop of an air conditioner.

That is, embodiments disclosed herein provide porous main body with a plurality of holes defined therein, which may act as the lamp supporter. Further, a parallel connection of a plurality of smaller UV lamps than a related art UV lamp may be provided on one surface of the porous main body.

Embodiments disclosed herein provide a smaller UV lamp with a smaller diameter than that of the related art UV lamp embodied as an external electrode lamp type for application to a wall-mounted air conditioner. Embodiments disclosed herein provide a porous main body with a plurality of holes with a same shape and size disposed around an air inlet.

Embodiments disclosed herein provide holders disposed on both sides of one surface of a porous main body in order for electrical connection and easy positioning of an external electrode UV lamp and an external electrode IR lamp. Embodiments disclosed herein also provide a plurality of IR lamps radiating IR rays in a direction of a heat exchanger. Further, embodiments disclosed herein provide a plurality of IR lamps arranged in parallel on a surface of a porous main body facing a vertical portion disposed in a lower portion of a heat exchanger.

Using the porous main body with the plurality of holes, the plurality of UV lamps and IR lamps may be supported and an air flow may be smoothly effected. Using the parallel arrangement of the plurality of smaller UV lamps, air may be sterilized uniformly along the front of the heat exchanger. Using the smaller UV lamp with a smaller diameter than that of the related art UV lamp, which is embodied as an external electrode lamp type, may have a more reduced width of the air flow direction than using a single UV lamp with a larger diameter. Further, the air conditioner may be more compacted using the above lamp configuration. For the wall-mounted air conditioner with a small inner space, the space efficiency, life span, and power consumption may be improved.

Using the porous main body with a plurality of holes with a same shape and size, which may be disposed around the air inlet, air entering into the air inlet may be aligned while passing through the plurality of holes. Thus, a concentration of air at a partial region of the plurality of UV lamps may be suppressed. Thus, the plurality of UV lamps may sterilize the air uniformly.

Using the holders provided on both sides of one surface of the porous main body, an electrical connection and positioning of the external electrode UV lamp and the external electrode IR lamp may be facilitated. Using a plurality of IR lamps which radiate IR rays in a direction of the heat exchanger, moisture remaining after an operation stop of the air conditioner may be removed to thereby prevent generation of molds.

Using a plurality of IR lamps arranged in parallel on a surface of the porous main body facing a vertical portion disposed or provided in a lower portion of the heat exchanger may allow air to be uniformly sterilized along a front of the heat exchanger.

The details of one or more embodiments are set forth in the accompanying drawings and the description. Other features will be apparent from the description and drawings, and from the claims.

Although embodiments have been described with reference to a number of illustrative embodiments thereof, it should be understood that numerous other modifications and embodiments can be devised by those skilled in the art that will fall within the spirit and scope of the principles of this disclosure. More particularly, various variations and modifications are possible in the component parts and/or arrangements of the subject combination arrangement within the scope of the disclosure, the drawings and the appended claims. In addition to variations and modifications in the component parts and/or arrangements, alternative uses will also be apparent to those skilled in the art.

Any reference in this specification to “one embodiment,” “an embodiment,” “example embodiment,” etc., means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment. The appearances of such phrases in various places in the specification are not necessarily all referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with any embodiment, it is submitted that it is within the purview of one skilled in the art to effect such feature, structure, or characteristic in connection with other ones of the embodiments.

Although embodiments have been described with reference to a number of illustrative embodiments thereof, it should be understood that numerous other modifications and embodiments can be devised by those skilled in the art that will fall within the spirit and scope of the principles of this disclosure. More particularly, various variations and modifications are possible in the component parts and/or arrangements of the subject combination arrangement within the scope of the disclosure, the drawings and the appended claims. In addition to variations and modifications in the component parts and/or arrangements, alternative uses will also be apparent to those skilled in the art. 

What is claimed is:
 1. An air conditioner, comprising: a main body; a fan to suction air into the main body; a filter received in the main body to filter air; a heat exchanger configured to allow heat exchange between a refrigerant and air suctioned into the main body; and a lamp module configured to radiate ultraviolet (UV) rays and infrared (IR) rays to the heat exchanger, wherein the lamp module includes a porous main body, a plurality of UV lamps, and a plurality of IR lamps, and wherein the plurality of UV lamps and the plurality of IR lamps are arranged in parallel on one surface of the porous main body at predetermined intervals.
 2. The air conditioner of claim 1, wherein the plurality of IR lamps is configured to be turned on when the plurality of UV lamps is turned off, and wherein the plurality of UV lamps is configured to be turned on when the plurality of IR lamps is turned off.
 3. The air conditioner of claim 1, wherein the plurality of UV lamps is turned on and off during an operation of the air conditioner, and the plurality of IR lamps is turned on and off during an operation stop of the air conditioner.
 4. The air conditioner of claim 1, wherein the plurality of UV lamps and the plurality of IR lamps are external electrode fluorescent lamps (EEFL).
 5. The air conditioner of claim 1, wherein the porous main body includes a plurality of first and second holders on first and second sides of one surface thereof, and wherein the plurality of UV lamps and the plurality of IR lamps are respectively coupled to the plurality of first and second holders.
 6. The air conditioner of claim 5, wherein the plurality of holders is shaped to partially wrap outer peripheral surfaces of the plurality of UV lamps and the plurality of IR lamps.
 7. The air conditioner of claim 1, wherein the porous main body has a horizontal width smaller than a horizontal width of the heat exchanger.
 8. The air conditioner of claim 1, further including a porous main body rotation mechanism to rotate the porous main body. 